Effective Connectivity Extracted from Resting-State fMRI Images Using Transfer Entropy - 15/09/23
, X. Chen a, M. Gao a, b, M. Hong a, Z. He a, H. Hong a, J. Shen cGraphical abstract |
Highlights |
• | Transfer entropy is used to construct whole-brain effective connectivity networks. |
• | Topological metrics of functional and effective networks were characterized. |
• | Effective networks contain a subset of highly interactive regions. |
Abstract |
Background and objective |
Based on magnetic resonance imaging (MRI), macroscopic structural and functional connectivity of human brain has been widely explored in the last decade. However, little work has been done on effective connectivity between individual brain parcels. In this preliminary study, we aim to investigate whole-brain effective connectivity networks from resting-state functional MRI (rs-fMRI) images.
Material and methods |
After the functional connectivity networks of 26 healthy subjects (aged from 25 to 35 years old) from Human Connectome Project database were derived from rs-fMRI images with dynamic time warping, proportional thresholding (PT) was performed on the functional connectivity matrices by retaining the PT% strongest functional connections. PT% ranges from 40% to 10% in steps of 5%. Then, effective connections corresponding to the PT% strongest functional connections, both bi-directional and unidirectional, were estimated with Renyi's 2-order transfer entropy (TE) method. Topological metrics of the built functional and effective connectivity networks were further characterized, including clustering coefficient, transitivity, and modularity.
Results |
It is found that the effective connectivity networks exhibit small world attributes, and that the networks contain a subset of highly interactive regions, including right frontal pole (in-degree 6), left middle frontal gyrus (in-degree 8, out-degree 1), right precentral gyrus (out-degree 9), left precentral gyrus (out-degree 7), right posterior division of supramarginal gyrus (in-degree 2, out-degree 3), left angular gyrus (out-degree 6), left inferior division of lateral occipital cortex (out-degree 6), right occipital pole (in-degree 5), right cerebellum 7b parcel (in-degree 15), and right cerebellum 8 parcel (in-degree 7, out-degree 1).
Conclusions |
The observations in this study provide information about the casual interactions among brain parcels in resting state, helping reveal how different subregions of large-scale distributed neural networks are coupled together in performing cognitive functions.
Le texte complet de cet article est disponible en PDF.Keywords : Effective connectivity, Functional connectivity, rs-fMRI, Graph, Transfer entropy
Plan
Vol 42 - N° 6
P. 457-465 - décembre 2021 Retour au numéro
Article précédent
- Dynamic Diet Planner: A Personal Diet Recommender System Based on Daily Activity and Physical Condition
- P. Ghosh, D. Bhattacharjee, M. Nasipuri
- Comparing the HRV Time-Series Signals Acquired from Cannabis Consuming and Non-Consuming Indian Paddy-Field Workers by Recurrence Quantification Analysis
- S.K. Nayak, K.K. Tarafdar, S. Banani, I. Banerjee, D. Kim, K. Pal
Bienvenue sur EM-consulte, la référence des professionnels de santé.
L’accès au texte intégral de cet article nécessite un abonnement.
Déjà abonné à cette revue ?